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//===-BlockGenerators.h - Helper to generate code for statements-*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines the BlockGenerator and VectorBlockGenerator classes, which
// generate sequential code and vectorized code for a polyhedral statement,
// respectively.
//
//===----------------------------------------------------------------------===//
#ifndef POLLY_BLOCK_GENERATORS_H
#define POLLY_BLOCK_GENERATORS_H
#include "polly/CodeGen/IRBuilder.h"
#include "polly/Support/GICHelper.h"
#include "polly/Support/ScopHelper.h"
#include "llvm/ADT/MapVector.h"
#include "llvm/Analysis/ScalarEvolutionExpressions.h"
#include "isl/map.h"
struct isl_ast_build;
struct isl_id_to_ast_expr;
namespace llvm {
class Pass;
class Region;
class ScalarEvolution;
} // namespace llvm
namespace polly {
using namespace llvm;
class ScopStmt;
class MemoryAccess;
class ScopArrayInfo;
class IslExprBuilder;
/// Generate a new basic block for a polyhedral statement.
class BlockGenerator {
public:
typedef llvm::SmallVector<ValueMapT, 8> VectorValueMapT;
/// Map types to resolve scalar dependences.
///
///@{
using AllocaMapTy = DenseMap<const ScopArrayInfo *, AssertingVH<AllocaInst>>;
/// Simple vector of instructions to store escape users.
using EscapeUserVectorTy = SmallVector<Instruction *, 4>;
/// Map type to resolve escaping users for scalar instructions.
///
/// @see The EscapeMap member.
using EscapeUsersAllocaMapTy =
MapVector<Instruction *,
std::pair<AssertingVH<Value>, EscapeUserVectorTy>>;
///@}
/// Create a generator for basic blocks.
///
/// @param Builder The LLVM-IR Builder used to generate the statement. The
/// code is generated at the location, the Builder points
/// to.
/// @param LI The loop info for the current function
/// @param SE The scalar evolution info for the current function
/// @param DT The dominator tree of this function.
/// @param ScalarMap Map from scalars to their demoted location.
/// @param EscapeMap Map from scalars to their escape users and locations.
/// @param GlobalMap A mapping from llvm::Values used in the original scop
/// region to a new set of llvm::Values. Each reference to
/// an original value appearing in this mapping is replaced
/// with the new value it is mapped to.
/// @param ExprBuilder An expression builder to generate new access functions.
/// @param StartBlock The first basic block after the RTC.
BlockGenerator(PollyIRBuilder &Builder, LoopInfo &LI, ScalarEvolution &SE,
DominatorTree &DT, AllocaMapTy &ScalarMap,
EscapeUsersAllocaMapTy &EscapeMap, ValueMapT &GlobalMap,
IslExprBuilder *ExprBuilder, BasicBlock *StartBlock);
/// Copy the basic block.
///
/// This copies the entire basic block and updates references to old values
/// with references to new values, as defined by GlobalMap.
///
/// @param Stmt The block statement to code generate.
/// @param LTS A map from old loops to new induction variables as
/// SCEVs.
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void copyStmt(ScopStmt &Stmt, LoopToScevMapT <S,
isl_id_to_ast_expr *NewAccesses);
/// Remove a ScopArrayInfo's allocation from the ScalarMap.
///
/// This function allows to remove values from the ScalarMap. This is useful
/// if the corresponding alloca instruction will be deleted (or moved into
/// another module), as without removing these values the underlying
/// AssertingVH will trigger due to us still keeping reference to this
/// scalar.
///
/// @param Array The array for which the alloca was generated.
void freeScalarAlloc(ScopArrayInfo *Array) { ScalarMap.erase(Array); }
/// Return the alloca for @p Access.
///
/// If no alloca was mapped for @p Access a new one is created.
///
/// @param Access The memory access for which to generate the alloca.
///
/// @returns The alloca for @p Access or a replacement value taken from
/// GlobalMap.
Value *getOrCreateAlloca(const MemoryAccess &Access);
/// Return the alloca for @p Array.
///
/// If no alloca was mapped for @p Array a new one is created.
///
/// @param Array The array for which to generate the alloca.
///
/// @returns The alloca for @p Array or a replacement value taken from
/// GlobalMap.
Value *getOrCreateAlloca(const ScopArrayInfo *Array);
/// Finalize the code generation for the SCoP @p S.
///
/// This will initialize and finalize the scalar variables we demoted during
/// the code generation.
///
/// @see createScalarInitialization(Scop &)
/// @see createScalarFinalization(Region &)
void finalizeSCoP(Scop &S);
/// An empty destructor
virtual ~BlockGenerator() {}
BlockGenerator(const BlockGenerator &) = default;
protected:
PollyIRBuilder &Builder;
LoopInfo &LI;
ScalarEvolution &SE;
IslExprBuilder *ExprBuilder;
/// The dominator tree of this function.
DominatorTree &DT;
/// The entry block of the current function.
BasicBlock *EntryBB;
/// Map to resolve scalar dependences for PHI operands and scalars.
///
/// When translating code that contains scalar dependences as they result from
/// inter-block scalar dependences (including the use of data carrying PHI
/// nodes), we do not directly regenerate in-register SSA code, but instead
/// allocate some stack memory through which these scalar values are passed.
/// Only a later pass of -mem2reg will then (re)introduce in-register
/// computations.
///
/// To keep track of the memory location(s) used to store the data computed by
/// a given SSA instruction, we use the map 'ScalarMap'. ScalarMap maps a
/// given ScopArrayInfo to the junk of stack allocated memory, that is
/// used for code generation.
///
/// Up to two different ScopArrayInfo objects are associated with each
/// llvm::Value:
///
/// MemoryType::Value objects are used for normal scalar dependences that go
/// from a scalar definition to its use. Such dependences are lowered by
/// directly writing the value an instruction computes into the corresponding
/// chunk of memory and reading it back from this chunk of memory right before
/// every use of this original scalar value. The memory allocations for
/// MemoryType::Value objects end with '.s2a'.
///
/// MemoryType::PHI (and MemoryType::ExitPHI) objects are used to model PHI
/// nodes. For each PHI nodes we introduce, besides the Array of type
/// MemoryType::Value, a second chunk of memory into which we write at the end
/// of each basic block preceding the PHI instruction the value passed
/// through this basic block. At the place where the PHI node is executed, we
/// replace the PHI node with a load from the corresponding MemoryType::PHI
/// memory location. The memory allocations for MemoryType::PHI end with
/// '.phiops'.
///
/// Example:
///
/// Input C Code
/// ============
///
/// S1: x1 = ...
/// for (i=0...N) {
/// S2: x2 = phi(x1, add)
/// S3: add = x2 + 42;
/// }
/// S4: print(x1)
/// print(x2)
/// print(add)
///
///
/// Unmodified IR IR After expansion
/// ============= ==================
///
/// S1: x1 = ... S1: x1 = ...
/// x1.s2a = s1
/// x2.phiops = s1
/// | |
/// | <--<--<--<--< | <--<--<--<--<
/// | / \ | / \ .
/// V V \ V V \ .
/// S2: x2 = phi (x1, add) | S2: x2 = x2.phiops |
/// | x2.s2a = x2 |
/// | |
/// S3: add = x2 + 42 | S3: add = x2 + 42 |
/// | add.s2a = add |
/// | x2.phiops = add |
/// | \ / | \ /
/// | \ / | \ /
/// | >-->-->-->--> | >-->-->-->-->
/// V V
///
/// S4: x1 = x1.s2a
/// S4: ... = x1 ... = x1
/// x2 = x2.s2a
/// ... = x2 ... = x2
/// add = add.s2a
/// ... = add ... = add
///
/// ScalarMap = { x1:Value -> x1.s2a, x2:Value -> x2.s2a,
/// add:Value -> add.s2a, x2:PHI -> x2.phiops }
///
/// ??? Why does a PHI-node require two memory chunks ???
///
/// One may wonder why a PHI node requires two memory chunks and not just
/// all data is stored in a single location. The following example tries
/// to store all data in .s2a and drops the .phiops location:
///
/// S1: x1 = ...
/// x1.s2a = s1
/// x2.s2a = s1 // use .s2a instead of .phiops
/// |
/// | <--<--<--<--<
/// | / \ .
/// V V \ .
/// S2: x2 = x2.s2a | // value is same as above, but read
/// | // from .s2a
/// |
/// x2.s2a = x2 | // store into .s2a as normal
/// |
/// S3: add = x2 + 42 |
/// add.s2a = add |
/// x2.s2a = add | // use s2a instead of .phiops
/// | \ / // !!! This is wrong, as x2.s2a now
/// | >-->-->-->--> // contains add instead of x2.
/// V
///
/// S4: x1 = x1.s2a
/// ... = x1
/// x2 = x2.s2a // !!! We now read 'add' instead of
/// ... = x2 // 'x2'
/// add = add.s2a
/// ... = add
///
/// As visible in the example, the SSA value of the PHI node may still be
/// needed _after_ the basic block, which could conceptually branch to the
/// PHI node, has been run and has overwritten the PHI's old value. Hence, a
/// single memory location is not enough to code-generate a PHI node.
///
/// Memory locations used for the special PHI node modeling.
AllocaMapTy &ScalarMap;
/// Map from instructions to their escape users as well as the alloca.
EscapeUsersAllocaMapTy &EscapeMap;
/// A map from llvm::Values referenced in the old code to a new set of
/// llvm::Values, which is used to replace these old values during
/// code generation.
ValueMapT &GlobalMap;
/// The first basic block after the RTC.
BasicBlock *StartBlock;
/// Split @p BB to create a new one we can use to clone @p BB in.
BasicBlock *splitBB(BasicBlock *BB);
/// Copy the given basic block.
///
/// @param Stmt The statement to code generate.
/// @param BB The basic block to code generate.
/// @param BBMap A mapping from old values to their new values in this
/// block.
/// @param LTS A map from old loops to new induction variables as
/// SCEVs.
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
///
/// @returns The copy of the basic block.
BasicBlock *copyBB(ScopStmt &Stmt, BasicBlock *BB, ValueMapT &BBMap,
LoopToScevMapT <S, isl_id_to_ast_expr *NewAccesses);
/// Copy the given basic block.
///
/// @param Stmt The statement to code generate.
/// @param BB The basic block to code generate.
/// @param BBCopy The new basic block to generate code in.
/// @param BBMap A mapping from old values to their new values in this
/// block.
/// @param LTS A map from old loops to new induction variables as
/// SCEVs.
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void copyBB(ScopStmt &Stmt, BasicBlock *BB, BasicBlock *BBCopy,
ValueMapT &BBMap, LoopToScevMapT <S,
isl_id_to_ast_expr *NewAccesses);
/// Generate reload of scalars demoted to memory and needed by @p Stmt.
///
/// @param Stmt The statement we generate code for.
/// @param LTS A mapping from loops virtual canonical induction
/// variable to their new values.
/// @param BBMap A mapping from old values to their new values in this block.
/// @param NewAccesses A map from memory access ids to new ast expressions.
void generateScalarLoads(ScopStmt &Stmt, LoopToScevMapT <S,
ValueMapT &BBMap,
__isl_keep isl_id_to_ast_expr *NewAccesses);
/// Generate instructions that compute whether one instance of @p Set is
/// executed.
///
/// @param Stmt The statement we generate code for.
/// @param Subdomain A set in the space of @p Stmt's domain. Elements not in
/// @p Stmt's domain are ignored.
///
/// @return An expression of type i1, generated into the current builder
/// position, that evaluates to 1 if the executed instance is part of
/// @p Set.
Value *buildContainsCondition(ScopStmt &Stmt, const isl::set &Subdomain);
/// Generate code that executes in a subset of @p Stmt's domain.
///
/// @param Stmt The statement we generate code for.
/// @param Subdomain The condition for some code to be executed.
/// @param Subject A name for the code that is executed
/// conditionally. Used to name new basic blocks and
/// instructions.
/// @param GenThenFunc Callback which generates the code to be executed
/// when the current executed instance is in @p Set. The
/// IRBuilder's position is moved to within the block that
/// executes conditionally for this callback.
void generateConditionalExecution(ScopStmt &Stmt, const isl::set &Subdomain,
StringRef Subject,
const std::function<void()> &GenThenFunc);
/// Generate the scalar stores for the given statement.
///
/// After the statement @p Stmt was copied all inner-SCoP scalar dependences
/// starting in @p Stmt (hence all scalar write accesses in @p Stmt) need to
/// be demoted to memory.
///
/// @param Stmt The statement we generate code for.
/// @param LTS A mapping from loops virtual canonical induction
/// variable to their new values
/// (for values recalculated in the new ScoP, but not
/// within this basic block)
/// @param BBMap A mapping from old values to their new values in this block.
/// @param NewAccesses A map from memory access ids to new ast expressions.
virtual void generateScalarStores(ScopStmt &Stmt, LoopToScevMapT <S,
ValueMapT &BBMap,
__isl_keep isl_id_to_ast_expr *NewAccesses);
/// Handle users of @p Array outside the SCoP.
///
/// @param S The current SCoP.
/// @param Inst The ScopArrayInfo to handle.
void handleOutsideUsers(const Scop &S, ScopArrayInfo *Array);
/// Find scalar statements that have outside users.
///
/// We register these scalar values to later update subsequent scalar uses of
/// these values to either use the newly computed value from within the scop
/// (if the scop was executed) or the unchanged original code (if the run-time
/// check failed).
///
/// @param S The scop for which to find the outside users.
void findOutsideUsers(Scop &S);
/// Initialize the memory of demoted scalars.
///
/// @param S The scop for which to generate the scalar initializers.
void createScalarInitialization(Scop &S);
/// Create exit PHI node merges for PHI nodes with more than two edges
/// from inside the scop.
///
/// For scops which have a PHI node in the exit block that has more than two
/// incoming edges from inside the scop region, we require some special
/// handling to understand which of the possible values will be passed to the
/// PHI node from inside the optimized version of the scop. To do so ScopInfo
/// models the possible incoming values as write accesses of the ScopStmts.
///
/// This function creates corresponding code to reload the computed outgoing
/// value from the stack slot it has been stored into and to pass it on to the
/// PHI node in the original exit block.
///
/// @param S The scop for which to generate the exiting PHI nodes.
void createExitPHINodeMerges(Scop &S);
/// Promote the values of demoted scalars after the SCoP.
///
/// If a scalar value was used outside the SCoP we need to promote the value
/// stored in the memory cell allocated for that scalar and combine it with
/// the original value in the non-optimized SCoP.
void createScalarFinalization(Scop &S);
/// Try to synthesize a new value
///
/// Given an old value, we try to synthesize it in a new context from its
/// original SCEV expression. We start from the original SCEV expression,
/// then replace outdated parameter and loop references, and finally
/// expand it to code that computes this updated expression.
///
/// @param Stmt The statement to code generate
/// @param Old The old Value
/// @param BBMap A mapping from old values to their new values
/// (for values recalculated within this basic block)
/// @param LTS A mapping from loops virtual canonical induction
/// variable to their new values
/// (for values recalculated in the new ScoP, but not
/// within this basic block)
/// @param L The loop that surrounded the instruction that referenced
/// this value in the original code. This loop is used to
/// evaluate the scalar evolution at the right scope.
///
/// @returns o A newly synthesized value.
/// o NULL, if synthesizing the value failed.
Value *trySynthesizeNewValue(ScopStmt &Stmt, Value *Old, ValueMapT &BBMap,
LoopToScevMapT <S, Loop *L) const;
/// Get the new version of a value.
///
/// Given an old value, we first check if a new version of this value is
/// available in the BBMap or GlobalMap. In case it is not and the value can
/// be recomputed using SCEV, we do so. If we can not recompute a value
/// using SCEV, but we understand that the value is constant within the scop,
/// we return the old value. If the value can still not be derived, this
/// function will assert.
///
/// @param Stmt The statement to code generate.
/// @param Old The old Value.
/// @param BBMap A mapping from old values to their new values
/// (for values recalculated within this basic block).
/// @param LTS A mapping from loops virtual canonical induction
/// variable to their new values
/// (for values recalculated in the new ScoP, but not
/// within this basic block).
/// @param L The loop that surrounded the instruction that referenced
/// this value in the original code. This loop is used to
/// evaluate the scalar evolution at the right scope.
///
/// @returns o The old value, if it is still valid.
/// o The new value, if available.
/// o NULL, if no value is found.
Value *getNewValue(ScopStmt &Stmt, Value *Old, ValueMapT &BBMap,
LoopToScevMapT <S, Loop *L) const;
void copyInstScalar(ScopStmt &Stmt, Instruction *Inst, ValueMapT &BBMap,
LoopToScevMapT <S);
/// Get the innermost loop that surrounds the statement @p Stmt.
Loop *getLoopForStmt(const ScopStmt &Stmt) const;
/// Generate the operand address
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
Value *generateLocationAccessed(ScopStmt &Stmt, MemAccInst Inst,
ValueMapT &BBMap, LoopToScevMapT <S,
isl_id_to_ast_expr *NewAccesses);
/// Generate the operand address.
///
/// @param Stmt The statement to generate code for.
/// @param L The innermost loop that surrounds the statement.
/// @param Pointer If the access expression is not changed (ie. not found
/// in @p LTS), use this Pointer from the original code
/// instead.
/// @param BBMap A mapping from old values to their new values.
/// @param LTS A mapping from loops virtual canonical induction
/// variable to their new values.
/// @param NewAccesses Ahead-of-time generated access expressions.
/// @param Id Identifier of the MemoryAccess to generate.
/// @param ExpectedType The type the returned value should have.
///
/// @return The generated address.
Value *generateLocationAccessed(ScopStmt &Stmt, Loop *L, Value *Pointer,
ValueMapT &BBMap, LoopToScevMapT <S,
isl_id_to_ast_expr *NewAccesses,
__isl_take isl_id *Id, Type *ExpectedType);
/// Generate the pointer value that is accesses by @p Access.
///
/// For write accesses, generate the target address. For read accesses,
/// generate the source address.
/// The access can be either an array access or a scalar access. In the first
/// case, the returned address will point to an element into that array. In
/// the scalar case, an alloca is used.
/// If a new AccessRelation is set for the MemoryAccess, the new relation will
/// be used.
///
/// @param Access The access to generate a pointer for.
/// @param L The innermost loop that surrounds the statement.
/// @param LTS A mapping from loops virtual canonical induction
/// variable to their new values.
/// @param BBMap A mapping from old values to their new values.
/// @param NewAccesses A map from memory access ids to new ast expressions.
///
/// @return The generated address.
Value *getImplicitAddress(MemoryAccess &Access, Loop *L, LoopToScevMapT <S,
ValueMapT &BBMap,
__isl_keep isl_id_to_ast_expr *NewAccesses);
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
Value *generateArrayLoad(ScopStmt &Stmt, LoadInst *load, ValueMapT &BBMap,
LoopToScevMapT <S,
isl_id_to_ast_expr *NewAccesses);
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void generateArrayStore(ScopStmt &Stmt, StoreInst *store, ValueMapT &BBMap,
LoopToScevMapT <S, isl_id_to_ast_expr *NewAccesses);
/// Copy a single PHI instruction.
///
/// The implementation in the BlockGenerator is trivial, however it allows
/// subclasses to handle PHIs different.
virtual void copyPHIInstruction(ScopStmt &, PHINode *, ValueMapT &,
LoopToScevMapT &) {}
/// Copy a single Instruction.
///
/// This copies a single Instruction and updates references to old values
/// with references to new values, as defined by GlobalMap and BBMap.
///
/// @param Stmt The statement to code generate.
/// @param Inst The instruction to copy.
/// @param BBMap A mapping from old values to their new values
/// (for values recalculated within this basic block).
/// @param GlobalMap A mapping from old values to their new values
/// (for values recalculated in the new ScoP, but not
/// within this basic block).
/// @param LTS A mapping from loops virtual canonical induction
/// variable to their new values
/// (for values recalculated in the new ScoP, but not
/// within this basic block).
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void copyInstruction(ScopStmt &Stmt, Instruction *Inst, ValueMapT &BBMap,
LoopToScevMapT <S, isl_id_to_ast_expr *NewAccesses);
/// Helper to determine if @p Inst can be synthesized in @p Stmt.
///
/// @returns false, iff @p Inst can be synthesized in @p Stmt.
bool canSyntheziseInStmt(ScopStmt &Stmt, Instruction *Inst);
/// Remove dead instructions generated for BB
///
/// @param BB The basic block code for which code has been generated.
/// @param BBMap A local map from old to new instructions.
void removeDeadInstructions(BasicBlock *BB, ValueMapT &BBMap);
/// Invalidate the scalar evolution expressions for a scop.
///
/// This function invalidates the scalar evolution results for all
/// instructions that are part of a given scop, and the loops
/// surrounding the users of merge blocks. This is necessary to ensure that
/// later scops do not obtain scalar evolution expressions that reference
/// values that earlier dominated the later scop, but have been moved in the
/// conditional part of an earlier scop and consequently do not any more
/// dominate the later scop.
///
/// @param S The scop to invalidate.
void invalidateScalarEvolution(Scop &S);
};
/// Generate a new vector basic block for a polyhedral statement.
///
/// The only public function exposed is generate().
class VectorBlockGenerator : BlockGenerator {
public:
/// Generate a new vector basic block for a ScoPStmt.
///
/// This code generation is similar to the normal, scalar code generation,
/// except that each instruction is code generated for several vector lanes
/// at a time. If possible instructions are issued as actual vector
/// instructions, but e.g. for address calculation instructions we currently
/// generate scalar instructions for each vector lane.
///
/// @param BlockGen A block generator object used as parent.
/// @param Stmt The statement to code generate.
/// @param VLTS A mapping from loops virtual canonical induction
/// variable to their new values
/// (for values recalculated in the new ScoP, but not
/// within this basic block), one for each lane.
/// @param Schedule A map from the statement to a schedule where the
/// innermost dimension is the dimension of the innermost
/// loop containing the statement.
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
static void generate(BlockGenerator &BlockGen, ScopStmt &Stmt,
std::vector<LoopToScevMapT> &VLTS,
__isl_keep isl_map *Schedule,
__isl_keep isl_id_to_ast_expr *NewAccesses) {
VectorBlockGenerator Generator(BlockGen, VLTS, Schedule);
Generator.copyStmt(Stmt, NewAccesses);
}
private:
// This is a vector of loop->scev maps. The first map is used for the first
// vector lane, ...
// Each map, contains information about Instructions in the old ScoP, which
// are recalculated in the new SCoP. When copying the basic block, we replace
// all references to the old instructions with their recalculated values.
//
// For example, when the code generator produces this AST:
//
// for (int c1 = 0; c1 <= 1023; c1 += 1)
// for (int c2 = 0; c2 <= 1023; c2 += VF)
// for (int lane = 0; lane <= VF; lane += 1)
// Stmt(c2 + lane + 3, c1);
//
// VLTS[lane] contains a map:
// "outer loop in the old loop nest" -> SCEV("c2 + lane + 3"),
// "inner loop in the old loop nest" -> SCEV("c1").
std::vector<LoopToScevMapT> &VLTS;
// A map from the statement to a schedule where the innermost dimension is the
// dimension of the innermost loop containing the statement.
isl_map *Schedule;
VectorBlockGenerator(BlockGenerator &BlockGen,
std::vector<LoopToScevMapT> &VLTS,
__isl_keep isl_map *Schedule);
int getVectorWidth();
Value *getVectorValue(ScopStmt &Stmt, Value *Old, ValueMapT &VectorMap,
VectorValueMapT &ScalarMaps, Loop *L);
Type *getVectorPtrTy(const Value *V, int Width);
/// Load a vector from a set of adjacent scalars
///
/// In case a set of scalars is known to be next to each other in memory,
/// create a vector load that loads those scalars
///
/// %vector_ptr= bitcast double* %p to <4 x double>*
/// %vec_full = load <4 x double>* %vector_ptr
///
/// @param Stmt The statement to code generate.
/// @param NegativeStride This is used to indicate a -1 stride. In such
/// a case we load the end of a base address and
/// shuffle the accesses in reverse order into the
/// vector. By default we would do only positive
/// strides.
///
/// @param NewAccesses A map from memory access ids to new ast
/// expressions, which may contain new access
/// expressions for certain memory accesses.
Value *generateStrideOneLoad(ScopStmt &Stmt, LoadInst *Load,
VectorValueMapT &ScalarMaps,
__isl_keep isl_id_to_ast_expr *NewAccesses,
bool NegativeStride);
/// Load a vector initialized from a single scalar in memory
///
/// In case all elements of a vector are initialized to the same
/// scalar value, this value is loaded and shuffled into all elements
/// of the vector.
///
/// %splat_one = load <1 x double>* %p
/// %splat = shufflevector <1 x double> %splat_one, <1 x
/// double> %splat_one, <4 x i32> zeroinitializer
///
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
Value *generateStrideZeroLoad(ScopStmt &Stmt, LoadInst *Load,
ValueMapT &BBMap,
__isl_keep isl_id_to_ast_expr *NewAccesses);
/// Load a vector from scalars distributed in memory
///
/// In case some scalars a distributed randomly in memory. Create a vector
/// by loading each scalar and by inserting one after the other into the
/// vector.
///
/// %scalar_1= load double* %p_1
/// %vec_1 = insertelement <2 x double> undef, double %scalar_1, i32 0
/// %scalar 2 = load double* %p_2
/// %vec_2 = insertelement <2 x double> %vec_1, double %scalar_1, i32 1
///
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
Value *generateUnknownStrideLoad(ScopStmt &Stmt, LoadInst *Load,
VectorValueMapT &ScalarMaps,
__isl_keep isl_id_to_ast_expr *NewAccesses);
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void generateLoad(ScopStmt &Stmt, LoadInst *Load, ValueMapT &VectorMap,
VectorValueMapT &ScalarMaps,
__isl_keep isl_id_to_ast_expr *NewAccesses);
void copyUnaryInst(ScopStmt &Stmt, UnaryInstruction *Inst,
ValueMapT &VectorMap, VectorValueMapT &ScalarMaps);
void copyBinaryInst(ScopStmt &Stmt, BinaryOperator *Inst,
ValueMapT &VectorMap, VectorValueMapT &ScalarMaps);
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void copyStore(ScopStmt &Stmt, StoreInst *Store, ValueMapT &VectorMap,
VectorValueMapT &ScalarMaps,
__isl_keep isl_id_to_ast_expr *NewAccesses);
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void copyInstScalarized(ScopStmt &Stmt, Instruction *Inst,
ValueMapT &VectorMap, VectorValueMapT &ScalarMaps,
__isl_keep isl_id_to_ast_expr *NewAccesses);
bool extractScalarValues(const Instruction *Inst, ValueMapT &VectorMap,
VectorValueMapT &ScalarMaps);
bool hasVectorOperands(const Instruction *Inst, ValueMapT &VectorMap);
/// Generate vector loads for scalars.
///
/// @param Stmt The scop statement for which to generate the loads.
/// @param VectorBlockMap A map that will be updated to relate the original
/// values with the newly generated vector loads.
void generateScalarVectorLoads(ScopStmt &Stmt, ValueMapT &VectorBlockMap);
/// Verify absence of scalar stores.
///
/// @param Stmt The scop statement to check for scalar stores.
void verifyNoScalarStores(ScopStmt &Stmt);
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void copyInstruction(ScopStmt &Stmt, Instruction *Inst, ValueMapT &VectorMap,
VectorValueMapT &ScalarMaps,
__isl_keep isl_id_to_ast_expr *NewAccesses);
/// @param NewAccesses A map from memory access ids to new ast expressions,
/// which may contain new access expressions for certain
/// memory accesses.
void copyStmt(ScopStmt &Stmt, __isl_keep isl_id_to_ast_expr *NewAccesses);
};
/// Generator for new versions of polyhedral region statements.
class RegionGenerator : public BlockGenerator {
public:
/// Create a generator for regions.
///
/// @param BlockGen A generator for basic blocks.
RegionGenerator(BlockGenerator &BlockGen) : BlockGenerator(BlockGen) {}
virtual ~RegionGenerator() {}
/// Copy the region statement @p Stmt.
///
/// This copies the entire region represented by @p Stmt and updates
/// references to old values with references to new values, as defined by
/// GlobalMap.
///
/// @param Stmt The statement to code generate.
/// @param LTS A map from old loops to new induction variables as SCEVs.
void copyStmt(ScopStmt &Stmt, LoopToScevMapT <S,
__isl_keep isl_id_to_ast_expr *IdToAstExp);
private:
/// A map from old to the first new block in the region, that was created to
/// model the old basic block.
DenseMap<BasicBlock *, BasicBlock *> StartBlockMap;
/// A map from old to the last new block in the region, that was created to
/// model the old basic block.
DenseMap<BasicBlock *, BasicBlock *> EndBlockMap;
/// The "BBMaps" for the whole region (one for each block). In case a basic
/// block is code generated to multiple basic blocks (e.g., for partial
/// writes), the StartBasic is used as index for the RegionMap.
DenseMap<BasicBlock *, ValueMapT> RegionMaps;
/// Mapping to remember PHI nodes that still need incoming values.
using PHINodePairTy = std::pair<PHINode *, PHINode *>;
DenseMap<BasicBlock *, SmallVector<PHINodePairTy, 4>> IncompletePHINodeMap;
/// Repair the dominance tree after we created a copy block for @p BB.
///
/// @returns The immediate dominator in the DT for @p BBCopy if in the region.
BasicBlock *repairDominance(BasicBlock *BB, BasicBlock *BBCopy);
/// Add the new operand from the copy of @p IncomingBB to @p PHICopy.
///
/// PHI nodes, which may have (multiple) edges that enter from outside the
/// non-affine subregion and even from outside the scop, are code generated as
/// follows:
///
/// # Original
///
/// Region: %A-> %exit
/// NonAffine Stmt: %nonaffB -> %D (includes %nonaffB, %nonaffC)
///
/// pre:
/// %val = add i64 1, 1
///
/// A:
/// br label %nonaff
///
/// nonaffB:
/// %phi = phi i64 [%val, %A], [%valC, %nonAffC], [%valD, %D]
/// %cmp = <nonaff>
/// br i1 %cmp, label %C, label %nonaffC
///
/// nonaffC:
/// %valC = add i64 1, 1
/// br i1 undef, label %D, label %nonaffB
///
/// D:
/// %valD = ...
/// %exit_cond = <loopexit>
/// br i1 %exit_cond, label %nonaffB, label %exit
///
/// exit:
/// ...
///
/// - %start and %C enter from outside the non-affine region.
/// - %nonaffC enters from within the non-affine region.
///
/// # New
///
/// polly.A:
/// store i64 %val, i64* %phi.phiops
/// br label %polly.nonaffA.entry
///
/// polly.nonaffB.entry:
/// %phi.phiops.reload = load i64, i64* %phi.phiops
/// br label %nonaffB
///
/// polly.nonaffB:
/// %polly.phi = [%phi.phiops.reload, %nonaffB.entry],
/// [%p.valC, %polly.nonaffC]
///
/// polly.nonaffC:
/// %p.valC = add i64 1, 1
/// br i1 undef, label %polly.D, label %polly.nonaffB
///
/// polly.D:
/// %p.valD = ...
/// store i64 %p.valD, i64* %phi.phiops
/// %p.exit_cond = <loopexit>
/// br i1 %p.exit_cond, label %polly.nonaffB, label %exit
///
/// Values that enter the PHI from outside the non-affine region are stored
/// into the stack slot %phi.phiops by statements %polly.A and %polly.D and
/// reloaded in %polly.nonaffB.entry, a basic block generated before the
/// actual non-affine region.
///
/// When generating the PHI node of the non-affine region in %polly.nonaffB,
/// incoming edges from outside the region are combined into a single branch
/// from %polly.nonaffB.entry which has as incoming value the value reloaded
/// from the %phi.phiops stack slot. Incoming edges from within the region
/// refer to the copied instructions (%p.valC) and basic blocks
/// (%polly.nonaffC) of the non-affine region.
///
/// @param Stmt The statement to code generate.
/// @param PHI The original PHI we copy.
/// @param PHICopy The copy of @p PHI.
/// @param IncomingBB An incoming block of @p PHI.
/// @param LTS A map from old loops to new induction variables as
/// SCEVs.
void addOperandToPHI(ScopStmt &Stmt, PHINode *PHI, PHINode *PHICopy,
BasicBlock *IncomingBB, LoopToScevMapT <S);
/// Create a PHI that combines the incoming values from all incoming blocks
/// that are in the subregion.
///
/// PHIs in the subregion's exit block can have incoming edges from within and
/// outside the subregion. This function combines the incoming values from
/// within the subregion to appear as if there is only one incoming edge from
/// the subregion (an additional exit block is created by RegionGenerator).
/// This is to avoid that a value is written to the .phiops location without
/// leaving the subregion because the exiting block as an edge back into the
/// subregion.
///
/// @param MA The WRITE of MemoryKind::PHI/MemoryKind::ExitPHI for a PHI in
/// the subregion's exit block.
/// @param LTS Virtual induction variable mapping.
/// @param BBMap A mapping from old values to their new values in this block.
/// @param L Loop surrounding this region statement.
///
/// @returns The constructed PHI node.
PHINode *buildExitPHI(MemoryAccess *MA, LoopToScevMapT <S, ValueMapT &BBMap,
Loop *L);
/// @param Return the new value of a scalar write, creating a PHINode if
/// necessary.
///
/// @param MA A scalar WRITE MemoryAccess.
/// @param LTS Virtual induction variable mapping.
/// @param BBMap A mapping from old values to their new values in this block.
///
/// @returns The effective value of @p MA's written value when leaving the
/// subregion.
/// @see buildExitPHI
Value *getExitScalar(MemoryAccess *MA, LoopToScevMapT <S, ValueMapT &BBMap);
/// Generate the scalar stores for the given statement.
///
/// After the statement @p Stmt was copied all inner-SCoP scalar dependences
/// starting in @p Stmt (hence all scalar write accesses in @p Stmt) need to
/// be demoted to memory.
///
/// @param Stmt The statement we generate code for.
/// @param LTS A mapping from loops virtual canonical induction variable to
/// their new values (for values recalculated in the new ScoP,
/// but not within this basic block)
/// @param BBMap A mapping from old values to their new values in this block.
/// @param LTS A mapping from loops virtual canonical induction variable to
/// their new values.
virtual void
generateScalarStores(ScopStmt &Stmt, LoopToScevMapT <S, ValueMapT &BBMAp,
__isl_keep isl_id_to_ast_expr *NewAccesses) override;
/// Copy a single PHI instruction.
///
/// This copies a single PHI instruction and updates references to old values
/// with references to new values, as defined by GlobalMap and BBMap.
///
/// @param Stmt The statement to code generate.
/// @param PHI The PHI instruction to copy.
/// @param BBMap A mapping from old values to their new values
/// (for values recalculated within this basic block).
/// @param LTS A map from old loops to new induction variables as SCEVs.
virtual void copyPHIInstruction(ScopStmt &Stmt, PHINode *Inst,
ValueMapT &BBMap,
LoopToScevMapT <S) override;
};
} // namespace polly
#endif
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